Abstract
AbstractStormwater ponds and retention basins are ubiquitous features throughout urban landscapes. These ponds are potentially important control points for nitrogen (N) removal from surface water bodies via denitrification. However, there are possible trade‐offs to this water quality benefit if high N and contaminant concentrations in stormwater pond sediments decrease the complete reduction of nitrous oxide (N2O), a potent greenhouse gas, to dinitrogen (N2) during denitrification. This may occur through decreasing the abundance or efficiency of denitrifiers capable of producing the N2O reductase enzyme. We predicted that ponds draining increasingly urbanized landscapes would have higher N and metal concentrations in their sediments, and thereby greater N2O yields. We measured potential denitrification rates, N2O reductase (nosZ) gene frequencies, as well as sediment and porewater chemistry in 64 ponds distributed across eight U.S. cities. We found almost no correlation between the proportion of urban land cover surrounding ponds and the nutrient and contaminant concentrations in the stormwater pond sediments within or across all cities. Regression analysis revealed that the proportion of potential N2 and N2O production that could be explained was under different environmental controls. Our survey raises many new questions about why N fluxes and transformations vary so widely both within and across urban environments, but also allays the concern that elevated metal concentrations in urban stormwater ponds will increase N2O emissions. Urban stormwater ponds are unlikely to be a problematic source of N2O to the atmosphere, no matter their denitrification potential.
Highlights
Urban stormwater runoff is a leading cause of surface water impairment throughout the developed and developing world (US EPA 2004, UNEP GEMS 2008)
Stormwater ponds may act as critical control points in watershed-scale nitrogen (N) retention by capturing particulate N and by supporting N removal through denitrification (Zhu et al 2004, Collins et al 2010, Bettez and Groffman 2012, Larson and Grimm 2012)
We found that emissions of N2 made up >90% of potential gaseous N emissions from most ponds and that approximately one-third of the variation in N2 production across all ponds could be explained by differences in the availability of inorganic nitrogen
Summary
Urban stormwater runoff is a leading cause of surface water impairment throughout the developed and developing world (US EPA 2004, UNEP GEMS 2008). Constructed stormwater retention and detention ponds are designed to reduce peak stormwater discharge and remove pollutants through passive sedimentation (NRC 2009). The construction of these ponds is a key way that municipalities attempt to reduce the impact of stormwater runoff on downstream water bodies (Bernhardt et al 2008). Denitrification is a microbially mediated process by which nitrate (NO3À) is reduced to gaseous N products (i.e., nitric oxide [NO], nitrous oxide [N2O], and dinitrogen [N2]) under low oxygen conditions It is the primary mechanism by which excess NO3À can be permanently removed before entering downstream aquatic ecosystems
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